FreeCalypso > hg > fc-magnetite
view src/cs/system/main/init.c @ 534:6c96725718c3
armio.c: C11x GPIO setup properly separated from C139
author | Mychaela Falconia <falcon@freecalypso.org> |
---|---|
date | Mon, 05 Nov 2018 17:10:06 +0000 |
parents | 838eeafb0051 |
children | 92dbfa906f66 |
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/* * INIT.C * * This module allows to initialize the board: * - wait states, * - unmask selected interrupts, * - initialize clock, * - disable watchdog. * Dummy functions used by the EVA3 library are defined. */ /* Config Files */ #ifndef _WINDOWS #include "l1sw.cfg" #include "rf.cfg" #include "chipset.cfg" #include "board.cfg" #include "swconfig.cfg" #include "fc-target.cfg" #if (OP_L1_STANDALONE == 0) #include "rv.cfg" #include "sys.cfg" #include "debug.cfg" #ifdef BLUETOOTH_INCLUDED #include "btemobile.cfg" #endif #ifdef BLUETOOTH #include "bluetooth.cfg" #endif #endif #if (OP_L1_STANDALONE == 0) #include "rv/rv_defined_swe.h" #endif #endif /* Include Files */ #include <assert.h> #include <ctype.h> #include <stdarg.h> #include <stdlib.h> #include <string.h> #include "nucleus.h" #include "sys_types.h" #include "l1_types.h" #include "l1_confg.h" #include "l1_const.h" #if TESTMODE #include "l1tm_defty.h" #endif // TESTMODE #if (AUDIO_TASK == 1) #include "l1audio_const.h" #include "l1audio_cust.h" #include "l1audio_defty.h" #endif // AUDIO_TASK #if (L1_GTT == 1) #include "l1gtt_const.h" #include "l1gtt_defty.h" #endif #if (L1_MP3 == 1) #include "l1mp3_defty.h" #endif #if (L1_MIDI == 1) #include "l1midi_defty.h" #endif #if (L1_AAC == 1) #include "l1aac_defty.h" #endif #if (L1_DYN_DSP_DWNLD == 1) #include "l1_dyn_dwl_defty.h" #endif #if (TRACE_TYPE == 4) #include "l1_defty.h" #endif #if ((OP_L1_STANDALONE == 1) && (CODE_VERSION != SIMULATION) && (PSP_STANDALONE == 0)) #if (AUDIO_TASK == 1) #include "l1audio_signa.h" #include "l1audio_msgty.h" #endif // AUDIO_TASK #if (L1_GTT == 1) #include "l1gtt_signa.h" #include "l1gtt_msgty.h" #endif #include "l1_defty.h" #include "cust_os.h" #include "l1_msgty.h" #include "nu_main.h" #include "l1_varex.h" #include "l1_proto.h" #include "hw_debug.h" #include "l1_trace.h" #endif /* ((OP_L1_STANDALONE == 1) && (CODE_VERSION != SIMULATION) && (PSP_STANDALONE==0)) */ #include "armio/armio.h" #include "timer/timer.h" #if (OP_L1_STANDALONE == 0) #include "rvf/rvf_api.h" #include "rvm/rvm_api.h" /* A-M-E-N-D-E-D! */ #include "sim/sim.h" #endif #include "abb/abb.h" #include "inth/iq.h" #include "tpudrv.h" #include "memif/mem.h" #include "clkm/clkm.h" #include "inth/inth.h" #if (OP_L1_STANDALONE == 1) #include "uart/serialswitch_core.h" #else #include "uart/serialswitch.h" #endif #include "uart/traceswitch.h" #include "dma/dma.h" #include "rhea/rhea_arm.h" #include "ulpd/ulpd.h" #if (PSP_STANDALONE == 0) #if (OP_L1_STANDALONE == 0) extern void ffs_main_init(void); extern void create_tasks(void); #if TI_NUC_MONITOR == 1 extern void ti_nuc_monitor_tdma_action( void ); #endif #if WCP_PROF == 1 #if PRF_CALIBRATION == 1 extern NU_HISR prf_CalibrationHISR; #endif #endif #else void l1ctl_pgm_clk32(UWORD32 nb_hf, UWORD32 nb_32khz); extern void L1_trace_string(char *s); #endif /* (OP_L1_STANDALONE) */ #endif #if (OP_L1_STANDALONE == 1) #if ((TRACE_TYPE==1) || (TRACE_TYPE==2) || (TRACE_TYPE==3) || (TRACE_TYPE==7) || TESTMODE) #include "uart/uart.h" /* * Serial Configuration set up. */ extern char ser_cfg_info[NUMBER_OF_TR_UART]; #include "rvt_gen.h" extern T_RVT_USER_ID trace_id; #endif #endif /* (OP_L1_STANDALONE == 1) */ /* * Serial Configuration set up. */ /* ** One config is: ** {XXX_BT_HCI, // Bluetooth HCI ** XXX_FAX_DATA, // Fax/Data AT-Cmd ** XXX_TRACE, // L1/Riviera Trace Mux ** XXX_TRACE}, // Trace PS ** ** with XXX being DUMMY, UART_IRDA or UART_MODEM */ #if ((((TRACE_TYPE==1) || (TRACE_TYPE==2) || (TRACE_TYPE==3) || (TRACE_TYPE==7) ||\ (TESTMODE)) && (OP_L1_STANDALONE == 1)) || (OP_L1_STANDALONE == 0)) #if (OP_L1_STANDALONE == 1) static T_AppliSerialInfo appli_ser_cfg_info = #else T_AppliSerialInfo appli_ser_cfg_info = #endif /* OP_L1_STANDALONE */ { #ifdef CONFIG_RVTMUX_ON_MODEM {DUMMY_BT_HCI, DUMMY_FAX_DATA, UART_MODEM_TRACE, DUMMY_TRACE}, // 0x0248 #else // RVTMUX_ON_MODEM {DUMMY_BT_HCI, UART_MODEM_FAX_DATA, UART_IRDA_TRACE, DUMMY_TRACE}, // default config = 0x0168 #endif #ifdef BTEMOBILE 12, // 12 serial config allowed #else // BTEMOBILE 9, // 9 serial config allowed #endif { // Configs with Condat Panel only {DUMMY_BT_HCI, DUMMY_FAX_DATA, DUMMY_TRACE, UART_IRDA_TRACE}, // 0x1048 {DUMMY_BT_HCI, DUMMY_FAX_DATA, DUMMY_TRACE, UART_MODEM_TRACE}, // 0x2048 // Configs with L1/Riviera Trace only {DUMMY_BT_HCI, DUMMY_FAX_DATA, UART_IRDA_TRACE, DUMMY_TRACE}, // 0x0148 {DUMMY_BT_HCI, DUMMY_FAX_DATA, UART_MODEM_TRACE, DUMMY_TRACE}, // 0x0248 // Configs with AT-Cmd only {DUMMY_BT_HCI, UART_MODEM_FAX_DATA, DUMMY_TRACE, DUMMY_TRACE}, // 0x0068 // Configs with Condat Panel and L1/Riviera Trace {DUMMY_BT_HCI, DUMMY_FAX_DATA, UART_MODEM_TRACE, UART_IRDA_TRACE}, // 0x1248 {DUMMY_BT_HCI, DUMMY_FAX_DATA, UART_IRDA_TRACE, UART_MODEM_TRACE}, // 0x2148 // Configs with Condat Panel and AT-Cmd {DUMMY_BT_HCI, UART_MODEM_FAX_DATA, DUMMY_TRACE, UART_IRDA_TRACE}, // 0x1068 #ifdef BTEMOBILE // Configs with L1/Riviera Trace and Bluetooth HCI {UART_IRDA_BT_HCI, DUMMY_FAX_DATA, UART_MODEM_TRACE, DUMMY_TRACE}, // 0x0249 {UART_MODEM_BT_HCI, DUMMY_FAX_DATA, UART_IRDA_TRACE, DUMMY_TRACE}, // 0x014A // Configs with AT-Cmd and Bluetooth HCI {UART_IRDA_BT_HCI, UART_MODEM_FAX_DATA, DUMMY_TRACE, DUMMY_TRACE}, // 0x0069 #endif // BTEMOBILE // Configs with L1/Riviera Trace and AT-Cmd {DUMMY_BT_HCI, UART_MODEM_FAX_DATA, UART_IRDA_TRACE, DUMMY_TRACE} // 0x0168 } }; #endif /* (TRACE_TYPE ...) || (OP_L1_STANDALONE == 0) */ /* * Init_Target * * Performs low-level HW Initialization. */ void Init_Target(void) { #if (BOARD == 5) #define WS_ROM (1) #define WS_RAM (1) #define WS_APIF (1) #define WS_CS2 (7) /* LCD on EVA3. */ #define WS_CS0 (7) /* DUART on EVA3. UART16750 and latch on A-Sample. */ #define WS_CS1 (7) /* LCD on A-Sample. */ IQ_InitWaitState (WS_ROM, WS_RAM, WS_APIF, WS_CS2, WS_CS0, WS_CS1); IQ_InitClock (2); /* Internal clock division factor. */ IQ_MaskAll (); /* Mask all interrupts. */ IQ_SetupInterrupts (); /* IRQ priorities. */ TM_DisableWatchdog (); /* * Reset all TSP and DBG fdefault values */ AI_ResetTspIO (); AI_ResetDbgReg (); AI_ResetIoConfig (); /* * Warning! The external reset signal is connected to the Omega and the * external device. If the layer 1 is used its initialization removes * the external reset. If the application does not use the layer 1 * you must remove the external reset (bit 2 of the reset control * register 0x505808). */ AI_ResetTspIO(); AI_ResetDbgReg(); AI_ResetIoConfig(); /* * Configure all IOs (see RD300 specification). */ AI_ConfigBitAsInput (1); AI_EnableBit (1); AI_ConfigBitAsOutput (2); AI_EnableBit (2); AI_ConfigBitAsInput (11); AI_EnableBit (11); AI_ConfigBitAsOutput (13); AI_EnableBit (13); AI_Power (1); /* Maintain power supply. */ #elif (BOARD == 6) || (BOARD == 7) || (BOARD == 8) || (BOARD == 9) || \ (BOARD == 40) || (BOARD == 41) || (BOARD == 42) || (BOARD == 43) || (BOARD == 45) || \ (BOARD == 35) || (BOARD == 46) || (BOARD == 70) || (BOARD == 71) #if (PSP_STANDALONE == 0) // RIF/SPI rising edge clock for ULYSSE //-------------------------------------------------- #if ((ANLG_FAM == 1) || (ANLG_FAM == 2) || (ANLG_FAM == 3)|| (ANLG_FAM == 11)) #if ((CHIPSET >= 3)) #if (CHIPSET == 12) F_CONF_RIF_RX_RISING_EDGE; F_CONF_SPI_RX_RISING_EDGE; #elif (CHIPSET == 15) //do the DRP init here for Locosto #if (L1_DRP == 1) // drp_power_on(); This should be done after the script is downloaded. #endif #else #if (BOARD==35) *((volatile SYS_UWORD16 *) ASIC_CONF) = 0x2000; #elif defined(CONFIG_TARGET_PIRELLI) /* * Pirelli's version of this Init_Target() function * in their fw sets the ASIC_CONF register to 0x6050, * which means PWL on the LT/PWL pin and LPG on the * DSR_MODEM pin. */ *((volatile SYS_UWORD16 *) ASIC_CONF) = 0x6050; #elif defined(CONFIG_TARGET_GTAMODEM) /* * The DSR_MODEM/LPG Calypso signal is unconnected on * Openmoko's modem, so let's mux it as LPG (output) * so it doesn't float, like Foxconn seem to have done * on the Pirelli. */ *((volatile SYS_UWORD16 *) ASIC_CONF) = 0x6040; #else *((volatile SYS_UWORD16 *) ASIC_CONF) = 0x6000; #endif /* (BOARD == 35) */ #endif #endif #endif /* ANLG(ANALOG)) */ #if (OP_L1_STANDALONE == 1) #if (BOARD == 40) || (BOARD == 41) || \ (BOARD == 42) || (BOARD == 43) || (BOARD == 45) // enable 8 Ohm amplifier for audio on D-sample AI_ConfigBitAsOutput (1); AI_SetBit(1); #elif (BOARD == 70) || (BOARD == 71) //Locosto I-sample or UPP costo board.BOARD // Initialize the ARMIO bits as per the I-sample spec // FIXME #endif #endif /* (OP_L1_STANDALONE == 1) */ #endif /* PSP_STANDALONE ==0 */ // Watchdog //-------------------------------------------------- TM_DisableWatchdog(); /* Disable Watchdog */ #if (CHIPSET == 12) || (CHIPSET == 15) TM_SEC_DisableWatchdog(); #endif #if ((CHIPSET == 4) || (CHIPSET == 7) || (CHIPSET == 8) || (CHIPSET == 10) || (CHIPSET == 11) || (CHIPSET == 12) || (CHIPSET == 15)) #if (CHIPSET == 12) #if 0 /* example of configuration for DMA debug */ #if (BOARD == 6) /* debug on EVA 4 , GPO2 must not be changed */ /* TPU_FRAME, NMIIT, IACKn */ F_DBG_IRQ_CONFIG(C_DBG_IRQ_IRQ4|C_DBG_IRQ_NMIIT|C_DBG_IRQ_IACKN); /* NDMA_REQ_VIEW1, NDMA_REQ_VIEW0, DMA_V(1), DMA_S(1), DMAREQ_P1(3:0)*/ F_DBG_DMA_P1_NDFLASH_CONFIG(C_DBG_DMA_P1_NDFLASH_NDMA_REQ_VIEW_1 | C_DBG_DMA_P1_NDFLASH_NDMA_REQ_VIEW_0 | C_DBG_DMA_P1_NDFLASH_DMA_REQ_P1_3 | C_DBG_DMA_P1_NDFLASH_DMA_REQ_P1_2 | C_DBG_DMA_P1_NDFLASH_DMA_REQ_P1_1 | C_DBG_DMA_P1_NDFLASH_DMA_REQ_P1_0 | C_DBG_DMA_P1_NDFLASH_DMA_REQ_S_1 | C_DBG_DMA_P1_NDFLASH_DMA_REQ_V1 ); /* DMA_REQ_S(2)*/ F_DBG_DMA_P2_CONFIG(C_DBG_DMA_P2_DMA_REQ_S2); /* DMA_CLK_REQ, BRIDGE_CLK */ F_DBG_CLK1_CONFIG(C_DBG_CLK1_DMA_CLK_REQ | C_DBG_CLK1_BRIDGE_CLK ); /* XIO_nREADY */ F_DBG_IMIF_CONFIG(C_DBG_IMIF_XIO_NREADY_MEM); /* DSP_nIRQ_VIEW1, DSP_nIRQ_VIEW0, BRIDGE_EN */ F_DBG_KB_USIM_SHD_CONFIG(C_DBG_KB_USIM_SHD_DSP_NIRQ_VIEW_1 | C_DBG_KB_USIM_SHD_DSP_NIRQ_VIEW_0 | C_DBG_KB_USIM_SHD_BRIDGE_EN ); /* RHEA_nREADY , RHEA_nSTROBE */ F_DBG_USIM_CONFIG(C_DBG_USIM_RHEA_NSTROBE | C_DBG_USIM_RHEA_NREADY ); /* XIO_STROBE */ F_DBG_MISC2_CONFIG(C_DBG_MISC2_X_IOSTRBN); /* DMA_CLK_REQ */ F_DBG_CLK2_CONFIG(C_DBG_CLK2_DMA_CLK_REQ2); /* DSP_IRQ_SEL0=DMA, DSP_IRQ_SEL1=DMA, DMA_REQ_SEL0=RIF_RX, DMA_REQ_SEL1=RIF_RX */ F_DBG_VIEW_CONFIG(0,0,C_DBG_DSP_INT_DMA, C_DBG_DSP_INT_DMA, C_DMA_CHANNEL_RIF_RX, C_DMA_CHANNEL_RIF_RX); #endif /* (BOARD == 6) */ #endif /* DMA debug example */ #else /* * Configure ASIC in order to output the DPLL and ARM clock */ // (*( volatile UWORD16* )(0xFFFEF008)) = 0x8000; // DPLL // (*( volatile UWORD16* )(0xFFFEF00E)) = 0x0004; // ARM clock // (*( volatile UWORD16* )(0xfffef004)) = 0x0600; // DSP clock + nIACK #endif /* (CHIPSET == 12) || CHIPSET == 15*/ /* * Enable/Disable of clock switch off for INTH, TIMER, BRIDGE and DPLL modules */ // IRQ, Timer and bridge may SLEEP // In first step, same configuration as SAMSON //-------------------------------------------------- #if (CHIPSET == 12) CLKM_INITCNTL(CLKM_IRQ_DIS | CLKM_TIMER_DIS | CLKM_BRIDGE_DIS | CLKM_DPLL_DIS); #elif (CHIPSET == 15) CLKM_INITCNTL(CLKM_IRQ_DIS | CLKM_TIMER_DIS | CLKM_CPORT_EN | CLKM_BRIDGE_DIS | 0x8000 ); /* CLKM_DPLL_DIS is remove by Ranga*/ #else CLKM_INITCNTL(CLKM_IRQ_DIS | CLKM_TIMER_DIS); // Select VTCXO input frequency //-------------------------------------------------- CLKM_UNUSED_VTCXO_26MHZ; // Rita RF uses 26MHz VCXO #if (RF_FAM == 12) CLKM_USE_VTCXO_26MHZ; #endif // Renesas RF uses 26MHz on F-sample but 13MHz on TEB #if (RF_FAM == 43) && (BOARD == 46) CLKM_USE_VTCXO_26MHZ; #endif #endif // Control HOM/SAM automatic switching //-------------------------------------------------- *((volatile unsigned short *) CLKM_CNTL_CLK) &= ~CLKM_EN_IDLE3_FLG; /* * The following part has been reconstructed from disassembly. */ RHEA_INITRHEA(0,0,0xFF); DPLL_INIT_BYPASS_MODE(DPLL_BYPASS_DIV_1); #if (CHIPSET == 8) DPLL_INIT_DPLL_CLOCK(DPLL_LOCK_DIV_1, 6); #elif (CHIPSET == 10) DPLL_INIT_DPLL_CLOCK(DPLL_LOCK_DIV_1, 8); #else #error "We only have DPLL setup for CHIPSETs 8 and 10" #endif CLKM_InitARMClock(0x00, 2, 0); /* no low freq, no ext clock, div by 1 */ /* * FreeCalypso change: memory timings and widths * are target-dependent. */ #ifdef CONFIG_TARGET_PIRELLI /* * Pirelli's version of this Init_Target() function * in their fw does the following: */ MEM_INIT_CS0(4, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS1(4, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS2(5, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS3(4, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS4(7, MEM_DVS_16, MEM_WRITE_EN, 0); #elif defined(CONFIG_TARGET_FCFAM) /* * The settings currently adopted for the FreeCalypso * hardware family, only nCS0, nCS1 and nCS2 are used * presently. */ MEM_INIT_CS0(4, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS1(4, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS2(4, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS3(4, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS4(4, MEM_DVS_16, MEM_WRITE_EN, 0); #elif defined(CONFIG_TARGET_DSAMPLE) && (CHIPSET == 8) /* * On D-Sample C05 (older Calypso silicon version) the clocks * run slower: the ARM clock runs at 39 MHz instead of 52 MHz. * Therefore, we need to use fewer wait states to effect * the same memory speed. */ MEM_INIT_CS0(2, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS1(2, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS2(2, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS3(2, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS4(0, MEM_DVS_8, MEM_WRITE_EN, 0); #else /* * The original settings from Openmoko, * only nCS0 and nCS1 are actually used, * same as on Mot C1xx phones, * the nCS2/3/4 settings are dummies from TI. */ MEM_INIT_CS0(3, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS1(3, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS2(5, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS3(3, MEM_DVS_16, MEM_WRITE_EN, 0); MEM_INIT_CS4(0, MEM_DVS_8, MEM_WRITE_EN, 0); #endif MEM_INIT_CS6(0, MEM_DVS_32, MEM_WRITE_EN, 0); MEM_INIT_CS7(0, MEM_DVS_32, MEM_WRITE_DIS, 0); RHEA_INITAPI(0,1); RHEA_INITARM(0,0); DPLL_SET_PLL_ENABLE; /* * Disable and Clear all pending interrupts */ #if (CHIPSET == 12) || (CHIPSET == 15) F_INTH_DISABLE_ALL_IT; // MASK all it F_INTH2_VALID_NEXT(C_INTH_IRQ); // reset current IT in INTH2 IRQ F_INTH_VALID_NEXT(C_INTH_IRQ); // reset current IT in INTH IRQ F_INTH_VALID_NEXT(C_INTH_FIQ); // reset current IT in INTH FIQ F_INTH_RESET_ALL_IT; // reset all IRQ/FIQ source #else INTH_DISABLEALLIT; #if 0 /* not present in our reference binary object */ INTH_RESETALLIT; #endif INTH_CLEAR; /* reset IRQ/FIQ source */ #endif // INTH //-------------------------------------------------- #if (CHIPSET == 12) || (CHIPSET == 15) #if (GSM_IDLE_RAM != 0) f_inth_setup((T_INTH_CONFIG *)a_inth_config_idle_ram); // setup configuration IT handlers #else f_inth_setup((T_INTH_CONFIG *)a_inth_config); // setup configuration IT handlers #endif #else IQ_SetupInterrupts(); #endif #if (CHIPSET == 12) || (CHIPSET == 15) #if (OP_L1_STANDALONE == 0) f_dma_global_parameter_set((T_DMA_TYPE_GLOBAL_PARAMETER *)&d_dma_global_parameter); #endif f_dma_channel_allocation_set(C_DMA_CHANNEL_0, C_DMA_CHANNEL_DSP); #if (OP_L1_STANDALONE == 1) f_dma_global_parameter_set((T_DMA_TYPE_GLOBAL_PARAMETER *)&d_dma_global_parameter); f_dma_channel_allocation_set(C_DMA_CHANNEL_0, C_DMA_CHANNEL_DSP); #endif #else // DMA //-------------------------------------------------- // channel0 = Arm, channel1 = Lead, channel2 = forced to Arm, channel3=forced to Arm, dma_burst = 0001, priority = same #if (OP_L1_STANDALONE == 0) DMA_ALLOCDMA(1,0,1,1); // Channel 1 used by DSP with RIF RX #endif #endif /* CHIPSET = 4 or 7 or 8 or 10 or 11 or 12 */ #else // RHEA Bridge //-------------------------------------------------- // ACCES_FAC_0 = 0, ACCES_FAC_1 = 0 ,TIMEOUT = 0x7F RHEA_INITRHEA(0,0,0x7F); #if (CHIPSET == 6) // WS_H = 1 , WS_L = 15 RHEA_INITAPI(1,15); // should be 0x01E1 for 65 Mhz #else // WS_H = 0 , WS_L = 7 RHEA_INITAPI(0,7); // should be 0x0101 for 65 Mhz #endif // Write_en_0 = 0 , Write_en_1 = 0 RHEA_INITARM(0,0); // INTH //-------------------------------------------------- INTH_DISABLEALLIT; // MASK all it INTH_CLEAR; // reset IRQ/FIQ source IQ_SetupInterrupts(); // DMA //-------------------------------------------------- // channel0 = Arm, channel1 = Lead, dma_burst = 0001, priority = same DMA_ALLOCDMA(1,0,1,1); // should be 0x25 (channel 1 = lead) #if (CHIPSET == 6) // Memory WS configuration for ULYSS/G1 (26 Mhz) board //----------------------------------------------------- MEM_INIT_CS2(2,MEM_DVS_16,MEM_WRITE_EN,0); #endif // CLKM //-------------------------------------------------- CLKM_InitARMClock(0x00, 2); /* no low freq, no ext clock, div by 1 */ #if (CHIPSET == 6) CLKM_INITCNTL(CLKM_IRQ_DIS | CLKM_BRIDGE_DIS | CLKM_TIMER_DIS | CLKM_VTCXO_26); #else CLKM_INITCNTL(CLKM_IRQ_DIS | CLKM_BRIDGE_DIS | CLKM_TIMER_DIS); #endif #endif /* CHIPSET = 4 or 7 or 8 or 10 or 11 or 12 */ // Freeze ULPD timer .... //-------------------------------------------------- *((volatile SYS_UWORD16 *) ULDP_GSM_TIMER_INIT_REG ) = 0; *((volatile SYS_UWORD16 *) ULDP_GSM_TIMER_CTRL_REG ) = TPU_FREEZE; // reset INC_SIXTEEN and INC_FRAC //-------------------------------------------------- #if (OP_L1_STANDALONE == 1) l1ctl_pgm_clk32(DEFAULT_HFMHZ_VALUE,DEFAULT_32KHZ_VALUE); #else ULDP_INCSIXTEEN_UPDATE(132); //32768.29038 =>132, 32500 => 133 // 26000 --> 166 ULDP_INCFRAC_UPDATE(15840); //32768.29038 =>15840, 32500 => 21845 // 26000 --> 43691 #endif /* OP_L1_STANDALONE */ // program ULPD WAKE-UP .... //================================================= #if (CHIPSET == 2) *((volatile SYS_UWORD16 *)ULDP_SETUP_FRAME_REG) = SETUP_FRAME; // 2 frame *((volatile SYS_UWORD16 *)ULDP_SETUP_VTCXO_REG) = SETUP_VTCXO; // 31 periods *((volatile SYS_UWORD16 *)ULDP_SETUP_SLICER_REG) = SETUP_SLICER; // 31 periods *((volatile SYS_UWORD16 *)ULDP_SETUP_CLK13_REG) = SETUP_CLK13; // 31 periods #else *((volatile SYS_UWORD16 *)ULDP_SETUP_FRAME_REG) = SETUP_FRAME; // 3 frames *((volatile SYS_UWORD16 *)ULDP_SETUP_VTCXO_REG) = SETUP_VTCXO; // 0 periods *((volatile SYS_UWORD16 *)ULDP_SETUP_SLICER_REG) = SETUP_SLICER; // 31 periods *((volatile SYS_UWORD16 *)ULDP_SETUP_CLK13_REG) = SETUP_CLK13; // 31 periods *((volatile SYS_UWORD16 *)ULPD_SETUP_RF_REG) = SETUP_RF; // 31 periods #endif // Set Gauging versus HF (PLL) //================================================= ULDP_GAUGING_SET_HF; // Enable gauging versus HF ULDP_GAUGING_HF_PLL; // Gauging versus PLL // current supply for quartz oscillation //================================================= #if (OP_L1_STANDALONE == 1) #if ((CHIPSET != 9) && (CHIPSET != 12) && (CHIPSET !=15)) // programming model changed for Ulysse C035, stay with default value *(volatile SYS_UWORD16 *)QUARTZ_REG = 0x27; #endif #else #if ((BOARD == 6) || (BOARD == 8) || (BOARD == 9) || (BOARD == 35) || (BOARD == 40) || (BOARD == 41)) *((volatile SYS_UWORD16 *)QUARTZ_REG) = 0x27; #elif (BOARD == 7) *((volatile SYS_UWORD16 *)QUARTZ_REG) = 0x24; #endif #endif /* OP_L1_STANDALONE */ // stop Gauging if any (debug purpose ...) //-------------------------------------------------- if ( *((volatile SYS_UWORD16 *) ULDP_GAUGING_CTRL_REG) & ULDP_GAUGING_EN) { volatile UWORD32 j; ULDP_GAUGING_STOP; /* Stop the gauging */ /* wait for gauging it*/ // one 32khz period = 401 periods of 13Mhz for (j=1; j<50; j++); while (! (* (volatile SYS_UWORD16 *) ULDP_GAUGING_STATUS_REG) & ULDP_IT_GAUGING); } #if (OP_L1_STANDALONE == 0) AI_ClockEnable (); #if (BOARD == 7) // IOs configuration of the B-Sample in order to optimize the power consumption AI_InitIOConfig(); // Set LPG instead of DSR_MODEM *((volatile SYS_UWORD16 *) ASIC_CONF) |= 0x40; // Reset the PERM_ON bit of LCR_REG *((volatile SYS_UWORD16 *) MEM_LPG) &= ~(0x80); #elif ((BOARD == 8) || (BOARD == 9)) // IOs configuration of the C-Sample in order to optimize the power consumption AI_InitIOConfig(); // set the debug latch to 0x00. *((volatile SYS_UWORD8 *) 0x2800000) = 0x00; #elif ((BOARD == 35) || (BOARD == 46)) AI_InitIOConfig(); // CSMI INTERFACE // Initialize CSMI clients for GSM control // and Fax/Data services CSMI_Init(); GC_Initialize(); // GSM control initialization CU_Initialize(); // Trace initialization CF_Initialize(); // Fax/Data pre-initialization #elif ((BOARD == 40) || (BOARD == 41)) // IOs configuration of the D-Sample in order to optimize the power consumption AI_InitIOConfig(); #ifdef BTEMOBILE // Reset BT chip by toggling the Island's nRESET_OUT signal *((volatile SYS_UWORD16 *) 0xFFFFFD04) |= 0x04; *((volatile SYS_UWORD16 *) 0xFFFFFD04) &= ~(0x4); #endif // set the debug latch to 0x0000. /* * FreeCalypso change: this write is only correct when running * on an actual D-Sample board, but not on any of the real-world * Calypso target devices. */ #ifdef CONFIG_TARGET_DSAMPLE *((volatile SYS_UWORD16 *) 0x2700000) = 0x0000; #endif #endif // BOARD // Enable HW Timers 1 & 2 TM_EnableTimer (1); TM_EnableTimer (2); #endif /* (OP_L1_STANDALONE == 0) */ #endif /* #if (BOARD == 5) */ } /* * Init_Drivers * * Performs Drivers Initialization. */ void Set_Switch_ON_Cause(void); void Init_Drivers(void) { #if (CHIPSET==15) bspI2c_init(); bspTwl3029_init(); #if (OP_L1_STANDALONE == 0) Set_Switch_ON_Cause(); #endif /* Turn on DRP We will make VRMCC to device group Modem * And Switch it on. */ bspTwl3029_Power_setDevGrp(NULL,BSP_TWL3029_POWER_VRMMC,BSP_TWL3029_POWER_DEV_GRP_MODEM); wait_ARM_cycles(convert_nanosec_to_cycles(100000*2)); bspTwl3029_Power_enable(NULL,BSP_TWL3029_POWER_VRMMC,BSP_TWL3029_POWER_STATE_ACTIVE); #endif #if (CHIPSET!=15) #if ABB_SEMAPHORE_PROTECTION // Create the ABB semaphore ABB_Sem_Create(); #endif // SEMAPHORE_PROTECTION #endif #if (OP_L1_STANDALONE == 0) /* * Initialize FFS invoking restore procedure by MPU-S */ #if ((BOARD == 35) || (BOARD == 46)) GC_FfsRestore(); #endif /* * FFS main initialization. */ ffs_main_init(); /* * Initialize Riviera manager and create tasks thanks to it. */ #if (CHIPSET!=15) || (REMU==0) rvf_init(); rvm_init(); /* A-M-E-M-D-E-D! */ create_tasks(); #endif /* * SIM Main Initialization. */ #if (CHIPSET!=15) SIM_Initialize (); #else bspUicc_bootInit(); #endif #endif } /* * Init_Serial_Flows * * Performs Serialswitch + related serial data flows initialization. */ void Init_Serial_Flows (void) { #if (OP_L1_STANDALONE == 0) /* * Initialize Serial Switch module. */ #if ((BOARD==35) || (BOARD == 46)) SER_InitSerialConfig (GC_GetSerialConfig()); #else SER_InitSerialConfig (&appli_ser_cfg_info); #endif /* * Then Initialize the Serial Data Flows and the associated UARTs: * - G2-3 Trace if GSM/GPRS Protocol Stack * - AT-Cmd/Fax & Data Flow * * Layer1/Riviera Trace Flow and Bluetooth HCI Flow are initialized * by the appropriate SW Entities. * * G2-3 Trace => No more Used */ SER_tr_Init(SER_PROTOCOL_STACK, TR_BAUD_38400, NULL); /* * Fax & Data / AT-Command Interpreter Serial Data Flow Initialization */ #if ((BOARD != 35) && (BOARD != 46)) (void) SER_fd_Initialize (); #endif #else /* OP_L1_STANDALONE */ #if (TESTMODE || (TRACE_TYPE==1) || (TRACE_TYPE==2) || (TRACE_TYPE==3) || (TRACE_TYPE==6) || (TRACE_TYPE==7)) #if ((BOARD == 35) || (BOARD == 46)) ser_cfg_info[UA_UART_0] = '0'; #else ser_cfg_info[UA_UART_0] = 'G'; #endif #if (CHIPSET !=15) ser_cfg_info[UA_UART_1] = 'R'; // Riviear Demux on UART MODEM #else ser_cfg_info[UA_UART_0] = 'R'; // Riviear Demux on UART MODEM #endif /* init Uart Modem */ SER_InitSerialConfig (&appli_ser_cfg_info); #if TESTMODE || (TRACE_TYPE == 1) || (TRACE_TYPE == 7) SER_tr_Init (SER_LAYER_1, TR_BAUD_115200, rvt_activate_RX_HISR); rvt_register_id("OTHER",&trace_id,(RVT_CALLBACK_FUNC)NULL); #else SER_tr_Init (SER_LAYER_1, TR_BAUD_38400, NULL); #endif L1_trace_string(" \n\r"); #endif /* TRACE_TYPE */ #endif /* OP_L1_STANDALONE */ } /* * Init_Unmask_IT * * Unmask all used interrupts. */ void Init_Unmask_IT (void) { IQ_Unmask(IQ_FRAME); IQ_Unmask(IQ_UART_IRDA_IT); IQ_Unmask(IQ_UART_IT); IQ_Unmask(IQ_ARMIO); #if (L1_DYN_DSP_DWNLD == 1) IQ_Unmask(IQ_API); #endif }